// RUN: %clang_builtins %s %librt -o %t && %run %t
// REQUIRES: librt_has_divsf3
#include "int_lib.h"
#include <stdio.h>
#include "fp_test.h"
// Returns: a / b
COMPILER_RT_ABI float __divsf3(float a, float b);
int test__divsf3(float a, float b, uint32_t expected)
{
float x = __divsf3(a, b);
int ret = compareResultF(x, expected);
if (ret){
printf("error in test__divsf3(%.20e, %.20e) = %.20e, "
"expected %.20e\n", a, b, x,
fromRep32(expected));
}
return ret;
}
int main()
{
// Returned NaNs are assumed to be qNaN by default
// qNaN / any = qNaN
if (test__divsf3(makeQNaN32(), 3.F, UINT32_C(0x7fc00000)))
return 1;
// NaN / any = NaN
if (test__divsf3(makeNaN32(UINT32_C(0x123)), 3.F, UINT32_C(0x7fc00000)))
return 1;
// any / qNaN = qNaN
if (test__divsf3(3.F, makeQNaN32(), UINT32_C(0x7fc00000)))
return 1;
// any / NaN = NaN
if (test__divsf3(3.F, makeNaN32(UINT32_C(0x123)), UINT32_C(0x7fc00000)))
return 1;
// +Inf / positive = +Inf
if (test__divsf3(makeInf32(), 3.F, UINT32_C(0x7f800000)))
return 1;
// +Inf / negative = -Inf
if (test__divsf3(makeInf32(), -3.F, UINT32_C(0xff800000)))
return 1;
// -Inf / positive = -Inf
if (test__divsf3(makeNegativeInf32(), 3.F, UINT32_C(0xff800000)))
return 1;
// -Inf / negative = +Inf
if (test__divsf3(makeNegativeInf32(), -3.F, UINT32_C(0x7f800000)))
return 1;
// Inf / Inf = NaN
if (test__divsf3(makeInf32(), makeInf32(), UINT32_C(0x7fc00000)))
return 1;
// 0.0 / 0.0 = NaN
if (test__divsf3(+0x0.0p+0F, +0x0.0p+0F, UINT32_C(0x7fc00000)))
return 1;
// +0.0 / +Inf = +0.0
if (test__divsf3(+0x0.0p+0F, makeInf32(), UINT32_C(0x0)))
return 1;
// +Inf / +0.0 = +Inf
if (test__divsf3(makeInf32(), +0x0.0p+0F, UINT32_C(0x7f800000)))
return 1;
// positive / +0.0 = +Inf
if (test__divsf3(+1.F, +0x0.0p+0F, UINT32_C(0x7f800000)))
return 1;
// positive / -0.0 = -Inf
if (test__divsf3(+1.F, -0x0.0p+0F, UINT32_C(0xff800000)))
return 1;
// negative / +0.0 = -Inf
if (test__divsf3(-1.F, +0x0.0p+0F, UINT32_C(0xff800000)))
return 1;
// negative / -0.0 = +Inf
if (test__divsf3(-1.F, -0x0.0p+0F, UINT32_C(0x7f800000)))
return 1;
// 1/3
if (test__divsf3(1.F, 3.F, UINT32_C(0x3eaaaaab)))
return 1;
// smallest normal result
if (test__divsf3(0x1.0p-125F, 2.F, UINT32_C(0x00800000)))
return 1;
// divisor is exactly 1.0
if (test__divsf3(0x1.0p+0F, 0x1.0p+0F, UINT32_C(0x3f800000)))
return 1;
// divisor is truncated to exactly 1.0 in UQ1.15
if (test__divsf3(0x1.0p+0F, 0x1.0001p+0F, UINT32_C(0x3f7fff00)))
return 1;
// smallest normal value divided by 2.0
if (test__divsf3(0x1.0p-126F, 2.0F, UINT32_C(0x00400000)))
return 1;
// smallest subnormal result
if (test__divsf3(0x1.0p-126F, 0x1p+23F, UINT32_C(0x00000001)))
return 1;
// some misc test cases obtained by fuzzing against h/w implementation
if (test__divsf3(-0x1.3e75e6p-108F, -0x1.cf372p+38F, UINT32_C(0x00000006)))
return 1;
if (test__divsf3(0x1.e77c54p+81F, -0x1.e77c52p-47F, UINT32_C(0xff800000)))
return 1;
if (test__divsf3(0x1.fffffep-126F, 2.F, UINT32_C(0x00800000)))
return 1;
return 0;
}